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On the Rolling Up of a Trailing Vortex Sheet

Published online by Cambridge University Press:  04 July 2016

G. J. Hancock*
Affiliation:
Department of Aeronautical Engineering, Queen Mary College, University of London

Extract

One of the best known results in finite wing theory, which is quoted in aerodynamic text books, states that the distance between two rolled up vortices behind a wing with an elliptic spanwise load distribution is sπ/2, where s is the wing semi-span. Within the framework of linear wing theory this result is correct. But it is of interest to enquire how this result is affected when the standard linear model becomes less valid, for example, at higher wing lift coefficients.

In this note, it is assumed that a continuous trailing vortex sheet rolls up into two discrete vortices. These two discrete vortices are assumed to have cores of finite radius; inside the cores the flow is taken to be solid body rotation, while the flow outside the cores is the standard irrotational vortex field. It is assumed that this rolling up process takes place far downstream of the finite wing which generates the trailing vorticity.

Type
Fifth Reynolds-Prandtl Memorial Lecture
Copyright
Copyright © Royal Aeronautical Society 1970 

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References

1. Sprieter, J. R. and Sacks, A. H. The Rolling Up of the Trailing Vortex Sheet and its Effect on the Downwash behind Wings. J Aero Sciences, Vol 18, 1951.Google Scholar
2. Hembold, H. B. Limitations of Circulation Lift. J Aero Sciences, Vol 24, 1957.Google Scholar
3. Ribner, H. S. On the Lift and Induced Drag Associated with Large Downwash Angles. UTIA Tech Note 19, 1958.Google Scholar
4. Hancock, G. J. Comments on the Limiting Circulatory Lift of a Wing of Finite Aspect Ratio. J Aero Sciences, Vol 27, January 1960.Google Scholar
5. Kaden, H. Aufwicklung einer Anstabilen Unstetigskeitsflache Ingen. Arch 2, 1931.Google Scholar
6. Westwater, F. L. Rolling Up of the Surface of Discontinuity behind an Aerofoil of Finite Span. R and M 1962,1936.Google Scholar
7. Cone, C. D. Jr A Theoretical Investigation of Vortex-Sheet Deformation behind a Highly Loaded Wing and its Effect on Lift. NASA TN D-657,1961.Google Scholar